Process of cleaning resins



Get. 15, 1940. J. w. TAYLOR PROCESS OF CLEANING RESINS Filed May 1o, 1939 3 Sheets-Sheet l JA/vfs 14./ 72m 0R J. TAYLOR PROCESS OF CLEANING RES-INS Oct. 15, 1940.

Filed May l0, 1959 3 Sheets-Sheet 2 JANE@ M/ Km0/f? Oct 15, 1940.

J. W. TAYLOR PROCESS oF CLEANING RESINS Filed May l0, 1939 3 Sheets-Sheet 3 y@ EF Patented Oct. 15,-1940 Y v UNITED STATES PATENT voi-'ticn PROCESS 0F CLEANING RESINS James W. Taylor, Pensacola, Fla., assigner to Peninsular-LurtonCompany, Pensacola, Fla., a corporation of Florida l,

Application May 10,193.9,soria1 No. 272,744

14 claims. (01.260-107) This invention relates to aprocess for removing thereof so that the sediment at the bottom of Vsolid foreign matter from the crude exudate or the tank will -not come threllgh at the first and oleoresin collected from pine trees and the like, rapidly 610g the llterS- Then, after the leSS D01- `as in the manufacture of gum rosin or other luted resin has been filtered, the settlings can be resins or gums. ltered through the same filters.V T 5 More speciiically the invention relates to a The retaining of the larger sized solid ingrediprocess for removing wood chips, bark, sand, inents in the perforatedb'asket, and the settling sects and other solid extraneous matter from the out of the denser solid impurities from the molten crude oleoresin, or turpentine, as it is collected resin, according to this process, greatly speeds from trees. up the cleaning operation and increases the ca- =1o This application is a continuation-in-part of pacity ofagiveniilter area.' "my copending application entitled: Apparatus It'iS, then, an Object 0f this inVentOn t0 DrO- `for cleaning resins, U. S. Serial No. 208,083, filed vide a process for rapidly and emciently remov- May 14, 1938. ing solid foreign matter from crude oleoresin and Oleoresin or gum as usually delivered to a reother resins, gums or the like. j15 -ning plant is in a very crude state containing Another Object 0f the invention iS t0 PrOVde many foreign bodies, According to this invena process fork cleaning oleoresin that includes a tion, said solid foreign bodies, or bodies of concoarse ltering operation to remove large Sized siderabiy higher melting points than the desired ysolid ingredients, a 'settling operation, and a finer oleoresin, are removed from the resin toI produce filtering OperatOnl' a purified product. A further object of the invention is to provide In .carrying out the processof this invention, "a PrOCeSSfOr rapidly Cleaning resin materi-al conf crude oleoresin, containing all of the usual solid taining foreign particles, Which prOCeSS inCludeS 'impur-ities therein, is dumped into a melting tank -a partial melting of the resinous material and a 5 having a perforated basket, plate or the like carecirculation of the melted material back to the 425 palole of retaining the larger sized solid foreign unmelted material, to speed up the melting opera- -particles The melting tank, or digester, is tiOnf'equipped with steam coils beneath the basket and A further object 0f the invention iS t0 provide extending around the 10Wer wall portion of the `a method of cleansing fusible material containing do basket. The heating tank or digester is sealed solid partielesof higher melting point by partial-'30;

from the atmosphere and steam is supplied to the lY melting the fusible material and Steam injectheating tank for melting a portion of the resin in ing the melted material back into the solid unthe basket, Y l melted material for speeding up the melting The melted resin drains to the bottom of the Operation- Y "heating tank, and when a, Sufficient quantity has 15"? Other and further bjCtS ofthe IlVeIltiOn Will {3*5 into the mass of resin in the basket to .speed-up 'entiOnbeen collected in thebottom of the tank, a steam beCOme" apparent t0 'those Skilled in the art from injector is actuated to further heat and recirthe fOllOWing detailed description 0f the annexed culat'e the me1ted resin back into the basket. sheets of drawings which disclose suitable apvThis recirculated heated resin is forced upwardly VDaratilS fnl'y Carrying Ont the pI'OCeSS 0f this in- .the melting operation. On the drawings: 4o When au of the resinous material has been -Figure 11s avertieai Cross-sectional View, with melted in the heatingv tank, the steam'injector "Parts Sho-Wn in elevation, of a cleaning deViCe is shut off and the finer solid impurities caembodying' this inVentiOn and ineluding a heat- D lpable of passing through the basket are allowed ing tank 0r digesterand a filter unit. '45

to settle to the bottom of the tank. This settling Figure 2 is a horizontal cross-sectional view operation removes .appreciable amounts of sand, f taken along the line Ile-II of VFigure 1. dirt and the like heavy solid materials. `Figure. 3 I is .a horizontal cross-sectional view After the settling operation, the molten resin -taken along thev line III--III ofFigure 1.

o .is forced through filters having extended'filtering Figure 4 is a detail view, partly insection, -of 5.250

- fthe heating tank at a point well abovethe' bottom shown in vertical section. e

surfaces, which are capable of retaining any rel` thesteamfjet'pumpforming'part ofthe apparatus maining solid ingredients entrained in the molten shown in Figure l;

jresin. Figure 5 is a broken elevational view of one of s Theresin lirst fed to the filtersis removed4 from the filtering tubes, with parts broken away Vand in elevation and with additional connected apparatus shown schematically.

Figure 10 is a broken vertical section of a modiTv fied form of filter unit, with parts shown in elevation. 'j i Figure 11 is an enlargedsectional view taken substantially on the line XI-XI of Figure 10.

Figure l2 is an enlarged; detail .view of the modified form ure 9.

As shown on the drawings :l y' In Fig. l the reference numeral I designates generally the heating tank or digester unit and the reference numeral I I designates generally the filter unit of theapparatus.

The heating tank I Il comp-rises a cylindrical of steam -mjector shown in Figlimperforate metal shell VI2 having a dished bottom head I3 riveted and/or welded to the lower end thereof. The head I3 has a central opening receiving a cylindrical sumpforming member I4, which is closed by a dished cap I5. A drain line 55, provided with a valve 56, isconnected through .said cap I5 to drainthe sumpso formed.

To the top portion of the cylinder I2 is welded a convergent ring I6, into the smaller upper end of which a cylindrical memberpII is fitted and welded. A reinforcing steel collar I8 is riveted or welded around the upper. end of the cylinder I'I, the edge I Ia of which is turned down over the outside of the collar I 8. Said collar I8 is provided with lug-s or ears IS/that project radially there- .from at spaced' intervals for pivotallysupporting eye bolts 20.

A cover 2 I closes theupper end of said tank I0. Said cover is provided, on its under surface with spaced annular rings 22 and 23 that form a groove for receiving the top edge IIa of the cylinder II. An annular gasket 24 Ais disposed in the groove between the rings 22 and 23 to form a seal for the coverV 2 I when the latter is clamped in place by means of nuts. 25 threaded on the eye Abolts 2B. `The eye bolts. 20 normally project y through radial slots ,26, n the periphery of the cover 2I.

In installing the .tankjIIIf it is convenient to have the cylindrical neck portion II extend through the floor F to facilitate the charging or loading operation. I

The cap 2l has a steam inlet pipe 21 threaded therethrough and carries a safety valve 28, which controls a discharge pipe 28a for venting steam, water vapor and vapors of spirits` of turpentine.

A spiral heating.; coil 30 is mounted in the bottom of the tank I0 on supports 3I, which are welded to the bottom headV I3.

An annularstearn header 32, as best shown in Figs. 1 and 2,is also mounted in the bottom above -the coil 30 on supports. 33 `welded to 'the bottom head I3. T'he supports 3-I: and 33V are positioned at' spaced intervals around the bottom head so as topermit flowfo'f :liquid from the top portion of the tank I0 into@ the sump I4.

. Spaced vertical steam pipes 34. extend upwardly from the header 32 Vto about mid-heightg'of the tank and terminate in an. upper; .annular fheader 35. Steam is supplied to the upper header 35 through a pipe 36 that passes through the side wall of the cylinder I2, any condensate and exhaust steam being removed from the bottom header 32 through a drain line 31 extending through the bottom head I3.

Steam is supplied at the center of the coil 30 through a pipe 38 (Fig. 2) and condensate and exhaust steam are removed at the outer end of the coil through a pipe 39.

An elongated cylindrical basket 40 of foraminous metal is mounted within the tank I0, with its bottom resting on top of the spiral coil 30 and with its upper end snugly fitting within the cylindrical neck II. Metal reinforcing rings 4I 'are secured around the top and bottom of the basket.4

the body of the'basket.

. A jet pump 43 is mounted in the sump I4 with its discharge leg 44 extending upwardly for a lshort distance through an opening provided for the' purpose in the bottom of the basket 40. As best shown in Figure 4, the jet pump `includes a restricted jet 45 fitted within a lower portion of the vertical leg 44 that is provided with circulating openings 43. A` valve 4l is provided for controlling flow of steam through the jet 45. In operation the molten resin, or other fluid substance in the sump is drawn in through the openings 46 by the action of the high velocity steam discharged through the jet 45. The mixture of steam .and molten resin-is thus drawn upwardly into the basket for a purpose to be more fully hereinafter described.

A pipe50 enters the side wall Aof the cylinder I2 abo-ve the bottom 'head I3 for conveying material from the tank I0 to the bottom of the filter unit I I. The pipe 58 has a T fitting 52V into which is connected a branch pipe 53 from the sump portion I4 of the tank Ill.` The pipe 58 and branch pipe l53 are provided with valves 5I and 54, respectively.

vThe filter unit II comprises' a cylindrical metal casing 60, the upper end of which also projects through the floor F. A bottom head BI, provided with a drain plug 62, iswelded to the lower end of the casing 60. l

A ring 63, secured around the top end of the casing 60 above the floor F, is providedwith laterally projecting peripherally spaced lugs or ears 64 for supporting svvingingjeye bolts-65.

A cap 6 6 having spaced rings S'I on the inner ,face thereof is adapted tofbe mounted on top of the casing, with the rings 61 forming an annular groove for receivinga gasket 68 that provides a seal between the top of the casing andzsaidcap 66. The periphery. of the cap'has spaced slots 69 into which the eye bolts 65 are swung when .the cap Ellis to `be clamped to the casing. Nuts .18 on the eye bolts 65 are turned down against 'the level of the mouth of .the pipe 50. A circular manifold' member 'I2 having a central opening dened'by a :boss I3 is threaded onfthe end of the pipe 'I I. The manifold member 'I2 has a plurality of upwardly flaring annular mouths 'I4 positioned at spaced intervals :around its periphery, six of such mouths being showninfFigur'e 3. Vertical fltering tubes 15 are seated attheir lower ends in the mouths 14 of the manifold 12 and are he1d therein by means of springs 16 compressed between the cap 66 and the upper closed ends .of said tubes. In this manner communication from the interior of each tube 15 is made with the pipe 1|.

The pipe 1| is connected to a discharge line 11 through an easily detachable union 18. Upon disconnection of said union 18 and release of the eye bolts 65, the cap 56, pipe 1|, manifold 12 and filtering tubes 15 may be lifted out bodily as a unit for cleaning or replacement. A valve 19 is provided in the line 11 and a steam inlet pipe 80 connected into said line 11 ahead of the valve for a purpose to be hereinafter more fullyT described.

As best shown in Figures 5 and 6, each of the lter tubes 15 comprises a perfo-rated metal cylinder 8| closed at the top thereof and having a convergent end 82 provided with an opening 83 at the bottom thereof. Each tapered end 82 is adapted to seat in a mouth 14 of the manifold 12. A filtering medium such as cotton batting, or a porous textile fabric or other ne mesh screening material 84 is wrapped or otherwise tightly disposed around the cylindrical portion of each tube 8| for the full length thereof.

Molten resin introduced into the casing 60 can thus :be forced through the filter screens 84 and the perforations of the tubes, 8| into said tubes 8| and thence into the manifold 12, from'which the resin passes upwardly under a pressure head out through the pipe 1 I.

If desired, perforated metal tub-es such as 15 can be replaced with wooden filtering units such as 90 disclosed in Figures '1 and 8. Each of the units 90 comprises a solid wooden rod 0| having longitudinally extending flutes 92 providing grooves or passageways 93 along the length of the rod, and a fine mesh screen sleeve 94 tightly disposed around the rod. Y

Each rod 9| has a convergent lower end 95, iiuted in the same manner as th-e length of the rod, that ts into a mouth 14 of the manifold 12 so that molten resin draining along the passageways 93 must now into the manifold.

As shown in Figure l, the bottom portion of the casing 60 has an inlet 96 through which steam may be introduced for agitating and vheating the contents of the casing, or for drying filter cakes on the tubes 15.

In carrying out the process of this invention, the crude oleoresin, gum, or other meltable solid is charged into the basket 40 of the tank |0. For the purposes of this description, it will be assumed that oleoresin is the particular material to be cleaned. The tank is then sealed by clamping the cover 2| thereon, and steam is introduced into the heating coil 30 and the bank of vertical heating tubes 34. The oleoresin in the bottom portion of the basket becomes quickly heated above its melting point and some molten oleoresin drains through the perforatio-ns of the basket into the bottom portion of the tank. The basket, however, retains the larger sized solid foreign matter.

When sucient material is melted and drained into the bo-ttom of the tank to cover the openings 46 of the jet pump 43, the valve 41 is opened to eject steam through the jet 45 and recirculate molten oleoresin back into the bottom portion of the basket 42 into Contact with the solid` resin remaining in the basket. The live steam so introduced through the jet pump increases the v temperature of the molten` oleoresin flowing therethrough and mixes directly therewith.

The operation is continued until all of the desired meltable material is in a flowable state. 'Ihe jet pump is then stopped by closing the valve 41 and the molten mass in the tank l0 is allowed to stand to permit the finer solid material passing through the basket 40 to settle into the sump I4. In this manner, heavier solid material such as sand and sediment settles out below the level of the pipe 50. l

After the settling operation, the valve 5| in the pipe line 50 is opened while the valve 54 in the branch pipe 53 remains closed.

Steam is introduced into the top of the tank I0 through the inlet pipe 21 to force the molten resin lying above the level of the pipe 50 into the casing 60 of the filter unit The valve 19 in the discharge line 11 connected with the pipe 1| is opened and the molten resin filling the casing 60 is forced through the filter screens into the tubes 15. The molt-en resin fiows down through the tubes 15 into the manifold 12 and is forced by the pressure differential existing between the interior of the casing and the interior of the pipe 1| upwardly through the pipe and into the line 11. If desired, steam may be introduced into the casing 50 through the inlet 95 to further heat the molten resin.

When the melted material in the tank I0 is drained down to the level of thepipe 50, the valve 5| is closed and the Valve 54 in the branch pipe 53 is opened to discharge the more polluted resin from the sump |4 into the casing 60' of the filtering unit for filtration thro-ugh the filter tubes 15.

The sediment beneath the level of the opening of the branch pipe 53 in the sump I4 can iinally be drained out through the drain line 55 by opening the valve 56.

After the filtering operation, the filter cake on the screens 84 of the tubes 15 can be removed or loosened, after closing the valve 19 in the drain line 11, by introducing steam 'throughl the inlet into the pipe 1| for flow through the tubes l5 and out of the perforations thereof to blow the lter cake off of the screen surfaces. The solid material removed from the tubes collects at the bottom of the casing 00, from which it can be removed by removal of the plug 62. The filter tubes themselves can be readily removed from the casing 60 by merely removing the cap 66 which releases the springs 16 `and permits the tubes tobe lifted out of the casing.

A process similar, in general, to that just described, may be carried out in a modied form of apparatus, such as that shown in Figs. 9 to 12 inclusive. In these figures of the drawings, the reference numeral |00 indicates generally a heating tank or digester of modified construction, and the reference numeral |0| a lter unit also of modified construction from that shown in Fig l. The heating tank |00 Vis provided with a lower sump chamber |02, above'which is mounted a perforated basket |03. Said basket |03 is supported in the lower portion of the tank |00 by means of a downwardly convergent 'flanged ring |04, which holds the basket with its walls `in spaced relation to the cylindrical side wall and convergent bottom wall of the tank. Heating coils |05 and |06 are positioned in the'space so formed. x

At the bottom of the sump |02 is provided a cross connection |01, intoone side branchof which extends a valve controlled steam pipe 08,

lfio

and into the lower branch of which extends a valve controlled steam pipe |09. Into the other side branch of the fitting |01 is secured a discharge pipe having a valve I. Said pipe ||0 joins an upper discharge pipe H2 by means of a cross fitting I I3. The pipe I I2 is tted into the lower cylindrical wall of the tank |30 at a point above the sloping bottom thereof and is provided with a valve I I4 for controlling the flow of melted oleoresins delivered from said tank |00 into the filter unit |0| through a continuation I |2a beyond said fitting I I3.

As best shown in Fig. 12, the vertical steam pipe |09 extends through the cross. fitting |07 and terminates in a jet ||5 within an inverted funnel-shaped member ||6 secured to the bottom of the basket |03. Steam introduced through the valve pipe |09 and jet H5 thus serves to draw melted oleoresins from the sump |02 back into the interior of the basket |03, in much the same fashion as the jet pump 43 of Fig. 1.

An additional feature of the modified form of heating tank shown in Fig. 9 includes a strainer pipe I I 'I extending vertically within the tank 900 for substantially the full length of the tank above the perforated basket |03. The lower portion of said strainer pipe is connected through the wall of the tank |00 by means of a pipe I8, provided with a valve ||9, to a T-fitting |20. A valved steam pipe IZI enters the top of said T-fitting |20, while a length of vertical piping |22 extends from the bottom side of said T-i'ltting |20 to the top branch of the cross tting ||3. The strainer pipe IIl is perforated throughout its length within the tank |00 and is provided with a wire strainer 23 covering it, Melted resins may thus pass through the strainer |23 and the perforations of the strainer pipe into the pipe I8 and becirculat'ed by the action of the steam entering through the valved pipe |2| through the pipe length |22 and back into the bottom of the tank |00 through the pipe ||2 and valve |4.

The top of the tank |00 is provided with a sealing cap or head |24. A steam inlet pipe |25 enters said head |24 for the admission of steam under sumcient pressure to force the melted contents of the tank over into the filter unit |Il| Said head |24 also carries a vent pipe |26 controlled by a safety valve |2'I, through which steam, water vapor and the vapor of spirits of turpentine are discharged into a pipe |28 leading to a condenser |29 and a storage tank |39.

The filter unit I 0| comprises a cylindrical shell |3| having an upper dished head |32 secured thereto and a lower removable head |33. Said head |33 comprisesan upper plate |34, a lower plate |35 and a spacing ring |36 joining'said plates to form a chamber |3'I therebetween. Said head |33 is securedgin place against the lower end of the cylindrical body portion |3| by means of swing bolts |38, a gasket |39 affording a tight seal therefor.

The pipe |2a is connected through a valve |60 by means of a coupling union |40 to a vertical length of pipe |4| which extends centrally through said head |33 and terminates in an open end |42 in spaced relation to the dished head |32 of said filter unit IGI, The filtering means proper comprise a plurality of concentric, cylindical filtering members |43 and |44, the upper ends of which are held in position by means of a winged retainer member |45 secured to the upper end of the pipe |4|. The lower ends of said filter members |43 and |44 fit into annular troughs |46 and |41, respectively, from which outlet nipples |48 and |49 discharge the jfiltrate into the chamber |31. Filtrate from said .chamber |31 may be withdrawn therefrom through an outlet pipe |50, while unfiltered residue is withdrawn through an outlet pipe |5| having an apertured end |52 extending into the main interior of the filter shell |3| above the upper plate |34.

Each of the lter members |43 and |44 comprises a cylinder |53, formed of Wood or other suitable material, and having luted inner and outer surfaces |54 and |55, respectively. Wire mesh screening |56 covers said outer and inner fiuted surfaces to permit the filtration of melted oleoresins therethrough into the channels provided by the fluting and thence into the collecting troughs |46 and |47. The upper ends of said channels, provided by the iiutings referred to, are covered by a connecting portion of said screening material |56 so as to prevent unfiltered oleoresions from entering said upper ends directly.

In the operation of the apparatus shown in Figs. 9 to 12 inclusive, the crude oleoresin is charged into the tank |00 to substantially ll the same. Steam is then admitted to the coils |05 and |06 to melt the-portion of the oleoresins contained within the basket |03. As soon as the oleoresin has become sufliciently heated to cause the sump |02 to become lled with molten oleoresins, steam is admitted through the pipe |09 and jet I5 to effect a recirculation of such melted portions through the contents of the basket |03, the force of the steam jet drawing such melted portion upwardly through the opening of the inverted funnel-Shaped member I6 into said basket. Either simultaneously with the operation of the steam jet ||5, or separately therefrom, steam is introduced through the valved pipe |2| into the fitting |20, the valves ||9 and ||4 being opened and the valves ||I and |60 being closed. The jet action of the steam issuing under pressure into the fitting |20 draws molten oleoresin through the strain pipe Il and circulates it down through the pipe length |22 and into the bottom of the heating tank through the pipe connection ||2. The heated mixture of steam and oleoresins flows upwardly about the steam coil |05 into the top of said heating tank and aids in the melting of unmelted portions of the charge. The cycle is repeated until the entire charge is completely melted.

During the introduction of direct steam into -the charge within the heating tank I0, the safety valve |21 is either set to relieve continuously, or is manipulated by the operator to vent as required by the demands of the system. Initially, during the heating operation, a large proportion of the steam injected into the charge condenses to form an emulsion with the oleoresin. As the heat liberated from the steam in condensing gradually raises the temperature of the mass, more and more of the steam is vented through the valve |21. Such steam carries with it vapors of spirits of turpentine, in order to recover which it is desirable to condense the steam and vapors in a condenser |29, from which the condensate is run into a storage tank |30. The turpentine may be recovered therefrom by simple distillation.

When the temperature of the mass reaches about F., the water and oleoresins begin to separate to some degree. The water can be observed forming into larger sized globules, and

lit

thevmass becomes thinner until a temperature of between 180? and 200 F. is reached, at which temperature the mass is in a highly melted state and the water, which theretofore formed a thick emulsion at the lower temperatures, does not interfere'with the filtration of the melted mass.

Alter the melting of the charge in the heating tank has been completed, the valves l I9, |2| and and the valves in the steam pipes |08 and |09 are closed, while the valve l|4 in the pipeline ||2 and the Valve |00 in the connecting pipeline ||2a are opened. Steam is then introduced into the top of the heating tank through the steam inlet pipe |25, with the release valve |2`| also closed, to force the liquid melt outthrough the pipe H2 and connecting pipe ||2a into the lter unit |0|. The molten mass passes up through the vertical pipe |4| and out the open end |42 thereof to spread over the top of the filter members |43 and |44. The diierential pressure on the outside and inside of said filter members, as caused by the steam pressure above the charge in the heating tank |00, forces the molten oleoresins through the filtering membrane covering said lter members, and the ltrate runs downwardly in the channels provided by the uting to collect in the concentric troughs |46 and |41, from which the iiltrate passes into the collecting chamber |31 and out through the outlet pipe |50. After all of the ltrable material has been passed through said filter members |43 and |44, a non-iiltrable residue is drained out through the pipe |5I.

As previously described, the more highly contaminated portion of the molten charge in the bottom of the heating tank |00 and in the sump |02 may be put through the filter unit |0| after the main body of the charge has been filtered. To do this, the, valve |4 is closed and the valves |08, |60 and are opened, and steam is introduced through the valve |08 toaid in forcing the remaining portion of the molten charge through the pipelines l0 and |2a into the filter unit |0|.

After the mixtureof oleoresin and condensate has passed through the lter unit, it is either placed in storage tanks or run into a batch still. If it is placed in a storage tank, emulsification again takes place as the mass cools. Any excess water settled out of. the rsaturatedi emulsion, either to the top or bottom of the storage tank, depending upon the gravity differential between the emulsion and water, may be drained off. If the hot mass is run directly into a batch still, the water is distilled off with the spirits of turpentine and the turpentine separated from the water by decantation. The rosin left in the still is run off into barrels, in which it solidiies upon cooling.

The process of the invention, as is evident from the above description, includes the recirculation of hot molten resin to assist in the melting of the remaining solid resin. Coarse solid particles are separated from the meltable material by being retained in the basket. The heavier, finer solids are separated by gravity settling, thereby increasing the capacity of the lters. 'Ihe process includes the recovery of clean resin from the sediment only after the filtration of the resin that has already been partially cleaned by the settling out step. In this manner the capacity of the ltering unit is greatly increased.

I am aware that many changes may be made and numerous details of the process may be varied through a wide range without departing from the principles of this invention, and I,

granted hereon otherwise than necessitated byV the prior art.

vI claim as my invention:

1. The process of cleansing oleoresin contain-A ing relatively infusible solid particles, which comprises heating a batch of crude oleoresin until a quantity of molten material has formed, separating said quantity of molten material from the unmelted portion of said batch, steam injecting the separated molten material back into saidv unmelted portion of the batch to melt any solid oleoresin remaining therein, continuing the heating and steam injection until all of the oleoresin of the batch is in a ilowable state, settling sand and sediment out of the molten oleoresin and forcing the oleoresin from a level above that of the settled out particles through a barrier capable of restraining the passage therethrough of solid particles suspended in the molten oleoresin.

f 2. The process of cleansing meltable'resin containing solid impurities of relatively higher melting points which comprises heating a batch of said resin to partially melt the resin, removing molten resin portionsthrough a barrier sized to,

retain the large solid impurities in the batch,

heating and recirculating the removed moltenr purities to the bottom of the pond, and separating the cleaner molten resin constituting the top portion of the pond vfrom the bottom portion.

3. The process of cleansing meltable resin containing solid impurities of relatively higher melting points which comprises heating a batch of said resin to partially melt the resin, removing molten resin portions through a barrier sized to retain the large solid impurities of the batch, heating and recirculating the removed molten resin portions through the unmelted portion of the batch, continuing the heating, removing, and recirculating until substantially all of the resin portion of the batch is molten, forming a pond of the molten resin, settling out iiner solid impurities to the bottom of the pond, applying a iiuid under pressure tothe top of the pond to create a positive pressure in the pond and successively blowing the top portion and the bottom portion of the pond through a barrier sized to retain the remaining solids in the molten resin.

4. In the process of refining crude oleoresin containing relatively higher melting point impurities, lthe steps which comprise heating a batch of said crude oleoresin to melt the oleoresin, withdrawing molten portions thereof free from large sized impurities, injecting steam directly into said withdrawn molten portions to heat the same and eiect circulation of said heat portions upwardly through unmelted remaining portions of said batch and continuing said withdrawing, heating and circulating operations until all of the oleoresin in said batch is in a -iiowable state.

5. In the process of refining crude oleoresin containing relatively higher melting point impurities, the steps which comprise heating a batch of said crude oleoresin arranged in a relatively deep vertical mass to melt the oleoresin, withdrawing molten portions thereof throughout a major part of the depth of said mass through a perforated barrier to free said portions from large sized impurities, injecting steam directly into said withdrawn molten portions to heat the same and effect circulation of said heated portions upwardly through unmelted remaining portions of said batch and continuing said withdrawing, heating and circulating operations until all of te oleorosin in said batch is in a owable state.

6. In the process of refining crude oleoresin containing relatively higher melting point impurities, the steps which comprise heating a batch of said crude oleoresin to melt the oleoresin, withdrawing molten portions thereof free from large sized impurities, injecting steam directly into said withdrawn molten portions to heat the same and effect circulation of said heat portions upwardly through unmelted remaining portions of said batch, continuing said withdrawing, heating and circulating operations until all of the oleoresin in said batch is in a flowable state, settling out settable solids from said flowable mass of oleoresin and filtering the said flowable mass to remove suspended solids therefrom.

7. In the process of refining resinous material containing relatively higher melting point solid impurities, the steps which comprise heating a mass of such material to partially melt the same,

forming a pond of molten material from said mass, allowing the molten material in said pond to stand to settle out settleable solid impurities, injecting, with a heating fluid, molten material in said pond from a level above the settled out solids therein back to the unmelted part of the mass to effect a further melting of the mass without agitating the settled solids in said pond.

8. The process of refining resinous material containing relatively` higher melting point solid impurities which comprises heating a mass of such resinous material to partially melt the same, separating said melted portion from the main unmelted part of the mass and from larger sized solid impurities, forming a quiescent pond of said melted portion, allowing finer solid particles in said molten portion to settle to the bottom of the pond, and steam injecting molten material from said pond at a level above the settled out solids therein directly back into the unmelted part of the mass to further melt the same without agitating the settled out solids in the pond.

9. In the process of cleansing fusible resinous and gummy material containing relatively infusible solid foreign particles, the steps which comprise supporting a charge of such fusible material above a perforate barrier, heating said charge to melt the fusible material and cause the molten material to pass through said barrier and form `a pond therebelow, and by means of a heating fluid'injecting molten material from a point in said pond above the bottom thereof back into the charge above said barrier to effect a further melting of said charge.

10. The method of cleansing fusible resinous and gummy material containing solid foreign particles, which comprises heating a batch of such material, separating the resulting molten portion from the unmelted material and from the larger sized solid particles therein, heating said separated molten portion and recirculating the same through the unmelted material of said batch until a molten mass of desired fluidity is obtained, settling out the finer solid foreign particles from said molten mass and filtering the remaining molten material to remove additional foreign particles.

11. The method of cleansing fusible resinous and gummy material containing relatively infusible solid foreign particles, which comprises heating a mass of said material to partially melt the same, filtering out the larger sized solid particles therein, removing already melted material from said mass before the whole is fully melted, injecting steam into the removed melted material to heat and recirculate the same through said mass to melt additional portions thereof, con- -f tinuing the injection of steam until the fusible material is all in a state of desired fluidity, allowing the ner sized solids to settle therefrom, and filtering the fluid material to remove suspended solid particles.

12. 'I'he method of cleansing crude resinous and gummy material containing relatively infusible solid foreign particles, which comprises indirectly heating a mass of such fusible material to partially melt the same, separating said melted f portion from the main unmelted part of said mass and from larger sized solid particles, injecting steam directly into said separated melted portion to heat and recirculate the same through said main unmelted part to completely melt said unmelted part, settling out finer solid particles from the resulting molten mass and thereafter filtering said molten mass.

13. In the process of heating resinous and gummy material containing relative infusible solid impurities, the steps which comprise heating a mass of such material to partially melt the same, withdrawing molten portions of the mass and recirculating the withdrawn molten material through the unmelted portion of the mass.

14. In the process of heating resinous and gummy material containing relatively infusible solid impurities, the steps which comprise heating a mass of such material to partially melt the same, withdrawing molten portions of the mass, recirculating the withdrawn molten material through the unmelted portion of the mass, and simultaneously further heating the withdrawn molten material as it is being recirculated.

JAMES W. TAYLOR.

(lll 

